Practical Quantum Mechanics

Similar documents
QUANTUM MECHANICS. Franz Schwabl. Translated by Ronald Kates. ff Springer

LECTURES ON QUANTUM MECHANICS

Quantum Mechanics: Fundamentals

P. W. Atkins and R. S. Friedman. Molecular Quantum Mechanics THIRD EDITION

QUANTUM MECHANICS SECOND EDITION G. ARULDHAS

Quantum Physics in the Nanoworld

Quantum Mechanics: Foundations and Applications

Quantum Physics II (8.05) Fall 2002 Outline

Physics of atoms and molecules

CONTENTS. vii. CHAPTER 2 Operators 15

Lectures on Quantum Mechanics

List of Comprehensive Exams Topics

PRINCIPLES OF PHYSICS. \Hp. Ni Jun TSINGHUA. Physics. From Quantum Field Theory. to Classical Mechanics. World Scientific. Vol.2. Report and Review in

Lecture Notes. Quantum Theory. Prof. Maximilian Kreuzer. Institute for Theoretical Physics Vienna University of Technology. covering the contents of

Topics for the Qualifying Examination

Students are required to pass a minimum of 15 AU of PAP courses including the following courses:

Harald Ibach Hans Lüth SOLID-STATE PHYSICS. An Introduction to Theory and Experiment

INTRODUCTION TO THE STRUCTURE OF MATTER

Contents. Preface to the First Edition Preface to the Second Edition

METHODS OF THEORETICAL PHYSICS

SOLID STATE PHYSICS. Second Edition. John Wiley & Sons. J. R. Hook H. E. Hall. Department of Physics, University of Manchester

Fundamentals of Spectroscopy for Optical Remote Sensing. Course Outline 2009

Symmetries in Quantum Physics

MOLECULAR SPECTROSCOPY

MODERN PHYSICS Frank J. Blatt Professor of Physics, University of Vermont

Generalization to Absence of Spherical Symmetry p. 48 Scattering by a Uniform Sphere (Mie Theory) p. 48 Calculation of the [characters not

A. F. J. Levi 1 EE539: Engineering Quantum Mechanics. Fall 2017.

Chemistry 483 Lecture Topics Fall 2009

FYS-6306 QUANTUM THEORY OF MOLECULES AND NANOSTRUCTURES

Quantum Field Theory 2 nd Edition

Frank Y. Wang. Physics with MAPLE. The Computer Algebra Resource for Mathematical Methods in Physics. WILEY- VCH WILEY-VCH Verlag GmbH & Co.

Contents. 1 Basic Equations 1. Acknowledgment. 1.1 The Maxwell Equations Constitutive Relations 11

Group Theory and Its Applications in Physics

Advanced quantum mechanics Reading instructions

CLASSICAL ELECTRICITY

Introduction to Modern Physics

Relativistic corrections of energy terms

Lecture 4 Quantum mechanics in more than one-dimension

Shigeji Fujita and Salvador V Godoy. Mathematical Physics WILEY- VCH. WILEY-VCH Verlag GmbH & Co. KGaA

Classical Electrodynamics

Quantum. Mechanics. Y y. A Modern Development. 2nd Edition. Leslie E Ballentine. World Scientific. Simon Fraser University, Canada TAIPEI BEIJING

Atoms and Molecules Interacting with Light Atomic Physics for the Laser Era

An Introduction to. Nuclear Physics. Yatramohan Jana. Alpha Science International Ltd. Oxford, U.K.

Coupling of Angular Momenta Isospin Nucleon-Nucleon Interaction

Spectra of Atoms and Molecules. Peter F. Bernath

The 3 dimensional Schrödinger Equation

Highenergy Nuclear Optics of Polarized Particles

Chemistry 3502/4502. Final Exam Part I. May 14, 2005

QUANTUM MECHANICS USING COMPUTER ALGEBRA

Time part of the equation can be separated by substituting independent equation

The Oxford Solid State Basics

NERS 311 Current Old notes notes Chapter Chapter 1: Introduction to the course 1 - Chapter 1.1: About the course 2 - Chapter 1.

INTRODUCTION TO NUCLEAR AND PARTICLE PHYSICS

Preface Introduction to the electron liquid

which implies that we can take solutions which are simultaneous eigen functions of

Quantum Physics III (8.06) Spring 2007 FINAL EXAMINATION Monday May 21, 9:00 am You have 3 hours.

Nuclear Physics for Applications

Department of Physics

Chemistry 3502/4502. Final Exam Part I. May 14, 2005

ψ s a ˆn a s b ˆn b ψ Hint: Because the state is spherically symmetric the answer can depend only on the angle between the two directions.

PHYSICS. Course Syllabus. Section 1: Mathematical Physics. Subject Code: PH. Course Structure. Electromagnetic Theory

Nuclear and Particle Physics

Quantum Field Theory. Kerson Huang. Second, Revised, and Enlarged Edition WILEY- VCH. From Operators to Path Integrals

Quantum Field Theory. and the Standard Model. !H Cambridge UNIVERSITY PRESS MATTHEW D. SCHWARTZ. Harvard University

Chemistry 881 Lecture Topics Fall 2001

Richard A. Mould. Basic Relativity. With 144 Figures. Springer-Verlag New York Berlin Heidelberg London Paris Tokyo Hong Kong Barcelona Budapest

The general solution of Schrödinger equation in three dimensions (if V does not depend on time) are solutions of time-independent Schrödinger equation

Mathematical Tripos Part IB Michaelmas Term Example Sheet 1. Values of some physical constants are given on the supplementary sheet

FYS 3510 Subatomic physics with applications in astrophysics. Nuclear and Particle Physics: An Introduction

Conclusion. 109m Ag isomer showed that there is no such broadening. Because one can hardly

An Introduction to the Standard Model of Particle Physics

Marcelo Alonso. Edward J. Finn. Georgetown University. Prentice Hall

msqm 2011/8/14 21:35 page 189 #197

Wolfgang Demtroder. Molecular Physics. Theoretical Principles and Experimental Methods WILEY- VCH. WILEY-VCH Verlag GmbH & Co.

Chem 467 Supplement to Lecture 19 Hydrogen Atom, Atomic Orbitals

Atomic Systems (PART I)

13. Basic Nuclear Properties

Physics 221A Fall 1996 Notes 19 The Stark Effect in Hydrogen and Alkali Atoms

Quantum Mechanics of Molecular Structures

Statistical Mechanics

Paradigms in Physics: Quantum Mechanics

MAGNETISM MADE SIMPLE. An Introduction to Physical Concepts and to Some Useful Mathematical Methods. Daniel C. Mattis

QUANTUM WELLS, WIRES AND DOTS

Electron Correlation

14. Structure of Nuclei

Notes on x-ray scattering - M. Le Tacon, B. Keimer (06/2015)

Lecture 4: Nuclear Energy Generation

Introduction to Modern Quantum Optics

Study Plan for Ph.D in Physics (2011/2012)

COPYRIGHTED MATERIAL. Index

Part I. Many-Body Systems and Classical Field Theory

is the minimum stopping potential for which the current between the plates reduces to zero.

Chem 442 Review for Exam 2. Exact separation of the Hamiltonian of a hydrogenic atom into center-of-mass (3D) and relative (3D) components.

M04M.1 Particles on a Line

Introduction to Mathematical Physics

Modern Optical Spectroscopy

Quantum Theory of Many-Particle Systems, Phys. 540

Problem 1: Spin 1 2. particles (10 points)

(8) Atomic Physics (1½l, 1½p)

Quantum Mechanics for Scientists and Engineers

Transcription:

Siegfried Flügge Practical Quantum Mechanics With 78 Figures Springer-Verlag Berlin Heidelberg New York London Paris Tokyo Hong Kong Barcelona Budapest

Contents Volume I I. General Concepts 1. Law of probability conservation 1 2. Variational principle of Schrödinger 2 3. Classical mechanics for space averages 5 4. Classical laws for angular motion 6 5. Energy conservation law 8 6. Hermitian conjugate 9 7. Construction of an hermitian operator 10 8. Derivatives of an operator 12 9. Time rate of an expectation value 13 10. Schrödinger and Heisenberg representations 14 11. Time dependent hamiltonian 17 12. Repeated measurement 18 13. Curvilinear coordinates 19 14. Momentum space wave functions 20 15. Momentum space: Periodic and aperiodic wave functions 22 П. One-Body Problems without Spin A. One-Dimensional Problems 25 16. Force-free case: Basic solutions 26 17. Force-free case: Wave packet 28 18. Standing wave 32 19. Opaque division wall 35 20. Opaque wall described by Dirac Ö function 39 21. Scattering at a Dirac 5 function wall 40 22. Scattering at a symmetric potential barrier 42 23. Reflection at a rectangular barrier 44 24. Inversion of reflection 47 25. Rectangular potential hole 48 26. Rectangular potential hole between two walls 52 27. Virtual levels 57

Contents Volume I IX 28. Periodic potential 62 29. Dirac comb 64 30. Harmonie oscillator 68 31. Oscillator in Hubert space 72 32. Oscillator eigenfunctions constructed by Hilbert space operators 74 33. Harmonic oscillator in matrix notation 76 34. Momentum space wave functions of oscillator 79 35. Anharmonic oscillator 80 36. Approximate wave functions 85 37. Potential step 86 38. Pöschl-Teller potential hole 89 39. Potential hole of modified Pöschl-Teller type 94 40. Free fall of a body over earth's surface 101 41. Accelerating electrical field 105 B. Problems of Two or Three Degrees of Freedom without Spherical Symmetry 107 42. Circular oscillator 107 43. Stark effect of a two-dimensional rotator 110 44. Ionized hydrogen molecule 113 45. Oblique incidence of a plane wave 118 46. Symmetrical top 121 С The Angular Momentum 125 47. Infinitesimal rotation 125 48. Components in polar coordinates 126 49. Angular momentum and Laplacian 129 50. Hilbert space transformations 130 51. Commutators in Schrödinger representation 132 52. Particles of spin 1 133 53. Commutation with a tensor 135 54. Quadrupole tensor. Spherical harmonics 136 55. Transformation of spherical harmonics 139 56. Construction of Hilbert space for an angular momentum component 141 57. Orthogonality of spherical harmonics 143 D. Potentials of Spherical Symmetry 144 a) Bound States 144 58. Angular momentum expectation values 147

X Contents Volume I 59. Construction of radial momentum operator 149 60. Solutions neighbouring eigenfunctions 152 61. Quadrupole moment 154 62. Particle enclosed in a sphere 155 63. Square well of finite depth 159 64. Wood-Saxon potential 162 65. Spherical oscillator 166 66. Degeneracy of the spherical oscillator 168 67. Kepler problem 171 68. Hulthen potential 175 69. Kratzer's molecular potential 178 70. Morse potential 182 71. Rotation correction of Morse formula 186 72. Yukawa potential hole 189 73. Isotope shift in x-rays 191 74. Muonic atom ground state 193 75. Central-force model of deuteron 196 76. Momentum space wave functions for central force potentials 200 77. Momentum space integral equation for central force potentials 202 78. Momentum space wave functions for hydrogen 204 79. Stark effect of a three-dimensional rotator 206 b) Problems of Elastic Scattering 208 80. Interference of incident and scattered waves 208 81. Partial wave expansion of plane wave 210 82. Partial wave expansion of scattering amplitude 213 83. Scattering at low energies 216 84. Scattering by a constant repulsive potential 218 85. Anomalous scattering 222 86. Scattering resonances 225 87. Contribution of higher angular momenta 229 88. Shape-independent approximation 231 89. Rectangular hole: Low-energy scattering 235 90. Low-energy scattering and bound state 238 91. Deuteron potential with and without hard core 240 92. Low-energy cross section with and without hard core.. 243 93. Low-energy scattering by a modified Pöschl-Teller potential hole 244 94. Radial integral equation 248 95. Variational principle of Schwinger 252

Contents Volume I XI 96. Successive approximations to partial-wave phase shift.. 254 97. Calogero's equation 258 98. Linearization of Calogero's equation 259 99. Scattering length for a negative-power potential 260 100. Second approximation to Calogero equation 263 101. Square-well potential: Scattering length 266 102. Scattering length for a Yukawa potential 268 103. Improvement of convergence in a spherical harmonics series 271 104. Collision-parameter integral 272 105. Born scattering: Successive approximation steps... 275 106. Scattering by a Yukawa potential 278 107. Scattering by an exponential potential 282 108. Born scattering by a charge distribution of spherical symmetry. 285 109. Hard sphere: High energy scattering 288 110. Rutherford scattering formula 290 111. Partial wave expansion for the Coulomb field 293 112.. Anomalous scattering 298 113. Sommerfeld-Watson transform 299 114. Reggepole 301 E. The Wentzel-Kramers-BriUouin (WKB) Approximation.. 303 115. Eikonal expansion 303 116. Radial WKB solutions 305 117. WKB boundary condition of Langer 306 118. Oscillator according to WKB approach 310 119. WKB eigenvalues in a homogeneous field 312 120. Kepler problem in WKB approach 314 121. WKB phases in the force-free case 316 122. Calculation of WKB phases 317 123. Coulomb phases by WKB method 318 124. Quasipotential 320 F. The Magnetic Field 322 125. Introduction of a magnetic field 322 126. Current in presence of a magnetic field 324 127. Normal Zeeman effect 326 128. Paramagnetic and diamagnetic susceptibilities without spin 328

Contents Volume II Ш. Particles with Spin A. One-Body Problems 1 129. Construction of Pauli matrices 1 130. Eigenstates of Pauli matrices 3 131. Spin algebra 6 132. Spinor transformation properties 7 133. Spin electron in a central field 9 134. Quadrupole moment of a spin state 12 135. Expectation values of magnetic moments 14 136. Fine structure 16 137. Plane wave of spin i particles 18 138. Free electron spin resonance 20 B. Two- and Three-Body Problems 22 139. Spin functions for two particles 22 140. Spin-dependent central force between nucleons 25 141. Powers of spin operators 26 142. Angular momentum eigenfunctions of two spin particles. 27 143. Tensor force operator 29 144. Deuteron with tensor interaction 31 145. Electrical quadrupole and magnetic dipole moments ofdeuteron 34 146. Spin functions of three particles 37 147. Neutron scattering by molecular hydrogen 40 IV. Many-Body Problems A. Few Particles 43 148. Two repulsive particles on a circle 43 149. Three-atomic linear molecule 47 150. Centre-of-mass motion 51

Contents Volume II XIII 151. Virial theorem 54 152. Slater determinant 55 153. Exchange in interaction terms with Slater determinant.. 57 154. Two electrons in the atomic ground state 58 155. Excited states of the helium atom 61 156. Excited S states of the helium atom 65 157. Lithium ground state 69 158. Exchange correction to lithium ground state 71 159. Dielectric susceptibility 74 160. Diamagnetic susceptibility of neon 76 161. Van der Waals attraction 78 162. Excitation degeneracy 80 163. Neutral hydrogen molecule 83 164. Scattering of equal particles 88 165. Anomalous proton-proton scattering 92 166. Inelastic scattering 95 B. Very Many Particles: Quantum Statistics 100 167. Electron gas in a metal 100 168. Paramagnetic susceptibility of a metal 102 169. Field emission, uncorrected for image force 105 170. Field emission, corrected for image force 108 171. White dwarf 113 172. Thomas-Fermi approximation 116 173. Amaldi correction for a neutral atom 121 174. Energy of a Thomas-Fermi atom 123 175. Virial theorem for the Thomas-Fermi atom 127 176. Tietz approximation of a Thomas-Fermi field 128 177. Variational approximation of Thomas-Fermi field.... 130 178. Screening of К electrons 131 V. Non-Stationary Problems 179. Two-level system with time-independent perturbation.. 135 180. Periodic perturbation of two-level system 137 181. Dirac perturbation method 140 182. Periodic perturbation: Resonance 142 183. Golden Rule for scattering 144 184. Born scattering in momentum space 147 185. Coulomb excitation of an atom 150 186. PhotoefTect 153

XIV Contents Volume II 187. Dispersion of light. Oscillator strengths 157 188. Spin flip in a magnetic resonance device 160 VI. The Relativ istic Dirac Equation 189. Iteration of the Dirac equation 165 190. Plane Dirac waves of positive energy 167 191. Transformation properties of a spinor 171 192. Lorentz covariants 172 193. Parity transformation 175 194. Charge conjugation 177 195. Mixed helicity states 179 196. Spin expectation value 180 197. Algebraic properties of a Dirac wave spinor 181 198. Current in algebraic formulation 184 199. Conduction current and polarization current 186 200. Splitting up of Dirac equations into two pairs 188 201. Central forces in Dirac theory 191 202. Kepler problem in Dirac theory 195 203. Hydrogen atom fine structure 198 204. Radial Kepler solutions at positive kinetic energies... 203 205. Angular momentum expansion of plane Dirac wave... 206 206. Scattering by a central force potential 209 207. Continuous potential step 213 208. Plane wave at a potential jump 219 209. Reflected intensity at a potential jump 222 VII. Radiation Theory 210. Quantization of Schrödinger field 227 211. Scattering in Born approximation 229 212. Quantization of classical radiation field 231 213. Emission probability of a photon 234 214. Angular distribution of radiation 236 215. Transition probability 239 216. Selection rules for dipole radiation 240 217. Intensities of Lyman lines 243 218. Compton effect 245 219. Bremsstrahlung 249

Contents Volume II XV Mathematical Appendix Coordinate systems 257 Г function 258 Bessel functions 260 Legendre functions 264 Spherical harmonics 267 The hypergeometric series 271 The confluent series 274 Some functions defined by integrals 276 Index for Volumes I and II 279

2024 © sciencedocbox.com Privacy Policy | Terms of Service | Feedback